Description:FIELD OF THE INVENTION
Our Invention is related to a ECG Splitter.

BACKGROUND OF THE INVENTION

Application of WSSThealthcare services can be improved by investing in a remote monitoring system, especially for the elderly who live alone or in distant locations with little access to institutions or medical facilities.

In this work, a smartphone-based remote monitoring system is created to monitor in real-time and deliver primary analysis, diagnosis, and treatment (first aid) all at once.

The proposed system helps reduce the death rate from chronic and common diseases related to the monitoring of critical parameters, such as ECG-HR, SpO2, RR, and temperature.

OBJECTIVES OF THE INVENTION
1. The objective of the invention is to provide a “ECG Splitter” is a ECG (Electrocardiogram) splitter is a medical device designed to facilitate the simultaneous recording of ECG signals from a single patient to multiple ECG machines.
2. The objective of the invention is to provide a ECG monitoring is a crucial aspect of cardiology and healthcare, providing valuable information about the electrical activity of the heart.
3. The objective of the invention is to provide a situations, it becomes necessary to record ECG signals from one patient to multiple ECG simultaneously, and that's where an ECG splitter comes into play.

SUMMARY OF THE INVENTION

A breakthrough in healthcare has been made with the usage of smartphone and wearable sensor technologies for remote monitoring.

This project aims to develop a smartphone-based remote real-time monitoring system for multiple physiological parameters (heart rate, respiration rate, temperature, blood oxygen saturation, and electrocardiogram) that takes into account high performance, auto alarm generation, warning transmission, and multi-method security.

Methods. Wearable sensor integrated circuits collected data on monitoring parameters, which were then collected by an Arduino Mega 250 R3. The gathered information was sent to a smartphone over a Wi-Fi interface.

The data was processed, analyzed, and presented in graphical and numerical formats using a patient application. +e abnormality threshold values of parameters were found and examined in order to create an autoalarm in the system.

Data from this alarm was then sent, via Wi-Fi and a third-generation (3G) mobile network, to a doctor application. The suggested system's performance was assessed and confirmed.

The suggested system was created to satisfy both primary (sensing, processing, displaying, autoalarm generation, real-time transmission, and threshold value identification) and secondary (compatibility, comfort, low cost and power consumption, small size, and appropriateness for ambulatory applications) requirements.

The system's average accuracy measurement of 99.26% indicates a satisfactory level of reliability. When communicating data to a medical application over Wi-Fi, the +e system shows an average time delay of 14 s, whereas when using a 3G mobile network, the average time delay is 68 s. +As time passes, the suggested system achieves minimal power usage.

(4 h 21 m 30 s) and the primary and secondary prerequisites for securely using remote data monitoring of several parameters at once. Conclusions.

If produced in sufficient quantities, the suggested technology can provide financial advantages for remotely monitoring patients who are isolated or live in rural regions, increasing medical services.
BRIEF DESCRIPTION OF THE DIAGRAM
Fig.1: ECG Splitter Flow.
Fig.2: ECG Splitter Graph.
DESCRIPTION OF THE INVENTION

A second Android component of the health application was made to display the data that was transferred from the patient application on a screen window. This component allowed medical professionals, such as physicians or responsible individuals from insurance companies or hospitals, to keep an eye on a patient's condition.
The emergency situations, diagnose and administer first aid. To ensure privacy, +e online portal requires a user name and ID/password. +e online interface offered numerical data for several patients to display on smartphones and Android devices, as well as video data (both graphic and numerical) captured by the patient application. Here's a brief introduction to the key aspects of an ECG splitter:
1. Purpose:
An ECG splitter is a device used to connect a single patient to multiple ECG (Electrocardiogram) machines. This is typically done in situations where monitoring the same patient's splitter allows for the distribution of the patient's ECG signals to multiple monitoring or recording devices.
2. Compatibility:
ECG splitters are designed to be compatible with standard ECG machines and monitoring systems. They should seamlessly integrate into existing setups, making it easy for healthcare providers to incorporate them into their practice.
3. Signal Quality:
Maintaining signal quality is crucial in ECG monitoring. Splitters are engineered to preserve the integrity of the electrical signals, ensuring that the recorded data is accurate and reliable for diagnostic purposes.
4. Flexibility:
Some ECG splitters offer flexibility in terms of the number of leads they can accommodate. This flexibility allows healthcare professionals to choose the configuration that best suits their diagnostic needs.
5. Patient Comfort:
ECG splitters should be designed with patient comfort in mind. The device should not cause discomfort. One ECG lead can connect to multiple ECG machine for analysis.
6. Clinical Applications:
ECG splitters find applications in various clinical settings, including hospitals, clinics, and ambulatory care. They are particularly useful during stress testing and other situations where a more comprehensive ECG assessment is needed.
Overview:
Here's a general overview of how an ECG splitter for a single patient to multiple ECG machines might work:
1. ECG Electrodes:
The patient is fitted with standard ECG electrodes that capture the electrical signals generated by the heart.
2. ECG Cable:
The ECG cable connects the electrodes to the ECG splitter.
3. ECG Splitter:
The ECG splitter is the key component that takes the incoming ECG signals from the patient and splits them into multiple outputs.
4. Multiple ECG Machines:
The outputs from the splitter are then connected to the input ports of multiple ECG machines. Each machine receives the same ECG signals from the patient in real-time.
5. Monitoring/Recording:
The connected ECG machines can be used for monitoring the patient's heart activity or recording the ECG signals for further analysis.
6. Signal Integrity:
It's crucial for the ECG splitter to maintain signal integrity, ensuring that the ECG signals reaching each connected machine are accurate and not distorted.

, Claims:I/WE CLAIMS
1) Our Invention “ECG Splitter” is a ECG (Electrocardiogram) splitter is a medical device designed to facilitate the simultaneous recording of ECG signals from a single patient to multiple ECG machines. ECG monitoring is a crucial aspect of cardiology and healthcare, providing valuable information about the electrical activity of the heart. In some situations, it becomes necessary to record ECG signals from one patient to multiple ECG simultaneously, and that's where an ECG splitter comes into play.
2) According to claim1# the invention is to a “ECG Splitter” is a ECG (Electrocardiogram) splitter is a medical device designed to facilitate the simultaneous recording of ECG signals from a single patient to multiple ECG machines.
3) According to claim1,2# the invention is to a ECG monitoring is a crucial aspect of cardiology and healthcare, providing valuable information about the electrical activity of the heart.
4) According to claim1,2,3# the invention is to a situations, it becomes necessary to record ECG signals from one patient to multiple ECG simultaneously, and that's where an ECG splitter comes into play.